JP5427370B2 - Multiple direction switching valve with bucket translation function - Google Patents

Description

  The present invention provides a multiple parallel movement function for holding a bucket in parallel by supplying pressure oil to the boom cylinder and operating the boom to supply the return pressure oil from the boom cylinder to the bucket cylinder. The present invention relates to a direction switching valve.

  As this type of technology, for example, there is one described in Patent Document 1. A multiple direction switching valve having a bucket parallel movement function described in Patent Document 1 includes a flow dividing valve that divides return pressure oil from a boom cylinder into a flow to a merge passage and a flow to a bypass passage, and a merge passage. A branch passage that branches and connects to the unload passage; and a switching valve that is provided in the branch passage and blocks or communicates with the branch passage. And according to the multiple direction switching valve described in Patent Document 1, it is possible to return the pressure oil to the unload passage through the branch passage branched from the merge passage, and to suppress the generation of pressure in the branch passage. And the flow of the return pressure oil from a boom cylinder to a bucket cylinder can be stopped by the switching valve provided in the branch passage, and the bucket parallel movement function can be canceled appropriately.

JP 2004-340313 A

  However, in the multiple direction switching valve having the bucket parallel movement function described in Patent Document 1, the switching valve that blocks or communicates the branch passage is disposed in the section adjacent to the flow dividing valve (FIG. 2 of Patent Document 1). , 4). For such a multi-directional valve, there is a demand for adding new functions such as a descending sequence valve, an ascending sequence valve, and a float solenoid valve. There was a problem that the continuous direction switching valve was enlarged.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to be able to suppress enlargement of the multi-directional valve, that is, a multi-unit having a bucket translation function that is more compact than conventional ones. A directional control valve is provided.

Means and effects for solving the problems

  In order to solve the above-described problems, the present invention provides an unload passage connected to a hydraulic pressure source, a tank passage connected to a tank, a boom section and connected to the unload passage. Boom direction switching valve that controls the supply of pressure oil to the boom cylinder, and a bucket that is disposed in the bucket section and connected to the unload passage, and controls the supply of pressure oil from the hydraulic source to the bucket cylinder A directional switching valve, a rising merging passage that supplies pressure oil from the rod side chamber of the boom cylinder to the head side chamber of the bucket cylinder via the boom directional switching valve, and the rising merging passage. An ascending diverter valve provided in a passage for controlling a flow rate of pressure oil supplied to a head side chamber of the bucket cylinder; An ascending branch passage branched from the ascending junction passage and connected to the unload passage or the tank passage; and disposed in the diversion section and provided in the ascending branch passage; Provided is a multi-directional directional switching valve having a bucket parallel movement function including a rising release switching valve in communication.

  According to this configuration, the ascending release switching valve and the ascending diversion valve are arranged in the same diversion section, whereby the ascending release switching valve section can be omitted. Thereby, the enlargement of the multiple direction switching valve can be suppressed as compared with the conventional case, that is, a compact multiple direction switching valve having a bucket parallel movement function can be obtained.

  In the present invention, the lowering confluence passage for supplying pressure oil from the head side chamber of the boom cylinder to the rod side chamber of the bucket cylinder via the boom direction switching valve, and the lowering passage are disposed in the diversion section. A lowering diverter valve provided in the merging passage for controlling the flow rate of the pressure oil supplied to the rod side chamber of the bucket cylinder, and a lowering branching from the lowering merging passage and connected to the unload passage or the tank passage And a lowering release switching valve arranged in the branching section and provided in the lowering branching passage and blocking or communicating with the lowering branching passage, the lowering branching valve and the ascent Are arranged parallel to each other, the ascending diverter valve is arranged on one side of the diverter section, and the descending diverter valve is arranged in front Disposed on the other side of the shunt section, it is preferable that the raising release switch valve is disposed on the one side of the same axis as the lowering diverter valve.

  According to this structure, the passage for connecting the lift release switching valve and the lift diversion valve is simplified by arranging the lift release switching valve and the lift diversion valve on the same one side in the flow dividing section. Can be

  Further, in the present invention, the ascending release switching valve has a bottomed cylindrical plug having a spool hole formed on the inner surface, and the descending diversion valve and the ascending release switching valve are provided at the bottom of the plug. It is preferable to arrange | position on the same axis line.

  According to this configuration, the storage space (spool hole) for the descending diversion valve and the ascending release switching valve can be formed by the same process, and the spool hole is easily formed.

  According to the second aspect of the present invention, the unload passage connected to the hydraulic pressure source, the tank passage connected to the tank, the boom section and the unload passage are connected to the unload passage, Boom direction switching valve that controls the supply of pressure oil from the hydraulic source to the boom cylinder, and disposed in the bucket section and connected to the unload passage to control the supply of pressure oil from the hydraulic source to the bucket cylinder A bucket direction switching valve, a descending junction passage for supplying pressure oil from the boom cylinder head side chamber to the bucket cylinder rod side chamber via the boom direction switching valve, and a branch section A lowering diversion valve that is provided in the lowering confluence passage and controls the flow rate of the pressure oil supplied to the rod side chamber of the bucket cylinder; A descending branch passage branched from the descending junction passage and connected to the unload passage or the tank passage, and disposed in the diversion section and provided in the descending branch passage, blocking the descending branch passage Alternatively, the present invention provides a multi-directional directional switching valve having a bucket parallel movement function including a lowering release switching valve in communication.

  According to this configuration, by arranging the lowering release switching valve and the lowering diversion valve in the same diversion section, the lowering release switching valve section can be omitted. Thereby, the enlargement of the multiple direction switching valve can be suppressed as compared with the conventional case, that is, a compact multiple direction switching valve having a bucket parallel movement function can be obtained.

  Further, in the present invention, the assembling passage for ascending that supplies pressure oil from the rod side chamber of the boom cylinder to the head side chamber of the bucket cylinder via the boom direction switching valve and the assembling passage are disposed in the diversion section. An ascending diverter valve that is provided in the merging passage and controls the flow rate of the pressure oil supplied to the head side chamber of the bucket cylinder, and an ascending branch from the ascending merging passage and connected to the unload passage or the tank passage And a release release switching valve disposed in the branching section and provided in the branching passage for raising and blocking or communicating with the branching passage for raising, and the branching valve for lowering and the lift Are arranged parallel to each other, the ascending diverter valve is arranged on one side of the diverter section, and the descending diverter valve is arranged in front Disposed on the other side of the shunt section, it is preferable that the lowering release switch valve is disposed on the other side of the same axis as the raising diverter valve.

  According to this configuration, by arranging the lowering release switching valve and the lowering diversion valve on the same other side in the diversion section, the passage connecting the lowering release switching valve and the lowering diversion valve can be simplified. Can be

  Further, in the present invention, the lowering release switching valve has a bottomed cylindrical plug having a spool hole formed on the inner surface, and the ascending diversion valve and the lowering release switching valve are provided at the bottom of the plug. It is preferable to arrange | position on the same axis line.

  According to this configuration, the storage space (spool hole) for the ascending diversion valve and the descending release switching valve can be formed by the same process, and the spool hole is easily formed.

  Hereinafter, the best mode for carrying out the present invention will be described with reference to the drawings.

(Configuration of multiple direction switching valve)
FIG. 1 is a hydraulic circuit diagram showing a multiple direction switching valve 1 (hereinafter referred to as “multiple direction switching valve 1”) having a bucket parallel movement function according to an embodiment of the present invention.
The multiple directional switching valve 1 is applied to a construction machine such as a loader (not shown), and a boom (not shown) attached to the front part of the loader so as to be tiltable is attached to the loader. A hydraulic operation unit such as a bucket (not shown) is provided. The boom is actuated by the boom cylinder 3 and rises when pressure oil is supplied to the head side chamber 3a of the boom cylinder 3, and descends when pressure oil is supplied to the rod side chamber 3b. The bucket is actuated by the bucket cylinder 4 and dumps (forward tilt direction) by supplying pressure oil to the head side chamber 4a of the bucket cylinder 4, and the pressure oil is supplied to the rod side chamber 3b (rear direction) (Tilt direction).

  As shown in FIG. 1, the multiple direction switching valve 1 includes a boom direction switching valve 11, a bucket direction switching valve 12, an ascending diversion valve 14, an ascending release switching valve 19, and a descending diversion valve. 15, a lowering release switching valve 20, an ascending sequence valve 16, a descending sequence valve 17, a float electromagnetic valve mechanism 18, and a service valve 13. The multiple direction switching valve 1 includes a pump 2 that is a hydraulic source, a boom cylinder 3 that operates a boom, a bucket cylinder 4 that operates a bucket, and a tank 5 that returns oil, respectively, a port 51, ports 52 and 53, The ports 54 and 55 and the port 60 are connected. In addition to these ports, the multiple direction switching valve 1 has ports 56, 57, 58, 59, 61, 62, 63 and the like.

  The unload passage 21 is connected to the pump 2 via the port 51, and the tank passage 22 is connected to the tank 5 via the port 60. If necessary, another valve (not shown) is connected to the port 63 provided on the most downstream side of the unload passage 21.

  The boom direction switching valve 11 is connected to the unload passage 21 and controls the supply of pressure oil from the pump 2 to the boom cylinder 3. The bucket direction switching valve 12 is connected to the unload passage 21 on the downstream side of the boom direction switching valve 11 and controls the supply of pressure oil from the pump 2 to the bucket cylinder 4. Further, the service valve 13 is connected to the unload passage 21 on the downstream side of the bucket direction switching valve 12, and pressure oil is supplied to hydraulic equipment (not shown) connected to the ports 58 and 59 as necessary. Control the supply. The boom direction switching valve 11, the bucket direction switching valve 12, and the service valve 13 are connected in series by an unload passage 21.

  The boom directional control valve 11 is connected to the ascending junction passage 23. The ascending junction passage 23 is a passage for supplying a part or all of the return pressure oil from the rod side chamber 3 b of the boom cylinder 3 to the head side chamber 4 a of the bucket cylinder 4 via the boom direction switching valve 11.

  A rising diversion valve 14 for controlling the flow rate of the pressure oil supplied to the head side chamber 4 a of the bucket cylinder 4 is provided in the rising confluence passage 23. A variable restrictor 31 is provided in the ascending merge passage 23 upstream of the ascending flow dividing valve 14, and the flow rate of the pressure oil supplied to the head side chamber 4 a of the bucket cylinder 4 and the unload passage 21 by the variable restrictor 31. The diversion ratio between the flow rate of the pressure oil flowing to and from is adjusted.

  Further, the multiple directional switching valve 1 is provided with an ascending branch passage 24 branched from the ascending junction passage 23 and connected to the unload passage 21, and the ascending branch passage 24 includes the ascending branch passage 24. An ascending release switching valve 19 that shuts off or communicates is provided. The lift release switching valve 19 blocks the lift branch passage 24 at the leveling operation position 19a, and brings the lift branch passage 24 into a communication state at the leveling release position 19b. The ascending branch passage 24 may be branched from the ascending junction passage 23 and connected to the tank passage 22.

  Further, the ascending sequence valve 16 is connected to the lowering confluence passage 25 downstream of the ascending diversion valve 14. The ascending sequence valve 16 is a valve provided to increase the accuracy of the bucket parallel movement, and controls the flow rate of the pressure oil flowing out from the rod side chamber 4 b of the bucket cylinder 4.

  Further, a lowering junction passage 25 is connected to the boom direction switching valve 11. The lowering joining passage 25 is a passage for supplying part or all of the return pressure oil from the head side chamber 3 a of the boom cylinder 3 to the rod side chamber 4 b of the bucket cylinder 4 via the boom direction switching valve 11.

  The lowering confluence passage 25 is provided with a lowering diversion valve 15 that controls the flow rate of the pressure oil supplied to the rod side chamber 4 b of the bucket cylinder 4. A variable throttle 32 is provided in the lowering confluence passage 25 upstream of the lowering diversion valve 15, and the flow rate of the pressure oil supplied to the rod side chamber 4 b of the bucket cylinder 4 and the unload passage 21 by the variable throttle 32. The diversion ratio between the flow rate of the pressure oil flowing to and from is adjusted.

  Further, the multiple direction switching valve 1 is provided with a descending branch passage 26 branched from the descending junction passage 25 and connected to the unload passage 21. The descending branch passage 26 includes the descending branch passage 26. A lowering release switching valve 20 that shuts off or communicates is provided. The lowering release switching valve 20 blocks the lowering branch passage 26 at the leveling operation position 20a, and brings the lowering branch passage 26 into a communication state at the leveling release position 20b. The descending branch passage 26 may be branched from the descending junction passage 25 and connected to the tank passage 22.

  Further, a descending sequence valve 17 is connected to the assembling passage 23 on the downstream side of the descending diversion valve 15. The descending sequence valve 17 is a valve provided to increase the accuracy of the bucket parallel movement, and controls the flow rate of the pressure oil flowing out from the head side chamber 4 a of the bucket cylinder 4.

  The multiple direction switching valve 1 is provided with a float solenoid valve mechanism 18 that connects the head side chamber 3 a and the rod side chamber 3 b of the boom cylinder 3 to the tank passage 22. The float electromagnetic valve mechanism 18 is operated by the electromagnetic switching valve 33, the switching valve 34 that is operated by the electromagnetic switching valve 33 and connects the rod side chamber 3 b of the boom cylinder 3 to the tank passage 22, and the boom switching cylinder 3 that is operated by the electromagnetic switching valve 33. And a switching valve 35 for connecting the head side chamber 3 a to the tank passage 22. Relief valves 41, 42a to 42f are provided at predetermined locations in the passage in the multiple direction switching valve 1, and the oil pressure is adjusted.

(Multi-directional directional valve structure)
FIG. 2 is a plan view of the multiple direction switching valve 1 shown in FIG. 3, FIG. 4, and FIG. 5 are a BB direction side view, a CC direction side view, and an AA sectional view, respectively, of the multiple direction switching valve 1 shown in FIG. 2 to 5, the same members and portions as those shown in FIG. 1 are denoted by the same reference numerals.

  As shown in FIGS. 2 to 4, the multiple direction switching valve 1 has a rectangular parallelepiped valve body 6, and ports 51 to 60 are provided on one surface of the valve body 6. Further, from the side of the valve body 6 in the B-B direction, the relief valve 41, the boom direction switching valve 11, the lowering diversion valve 15, the lowering release switching valve 20, the lowering sequence valve 17, the bucket direction switching valve 12, And the end portions of the service valve 13 and the like protrude. Further, from the side surface of the valve body 6 in the C-C direction, the electromagnetic switching valve 33 for float, the direction switching valve 11 for boom, the diversion valve 14 for raising, the release switching valve 19 for raising, the sequence valve 16 for raising, the direction for bucket Ends such as the switching valve 12 and the service valve 13 protrude. The valve body 6 is a casting.

  The multiple direction switching valve 1 includes, in order from one side, a float section 81 in which an electromagnetic switching valve 33 for float is disposed, a boom section 82 in which a boom direction switching valve 11 is disposed, and diversion valves 14 and 15. Are divided into six sections: a divided flow section 83, a sequence section in which sequence valves 16 and 17 are disposed, a bucket section in which bucket directional control valve 12 is disposed, and a service section in which service valve 13 is disposed. . Here, both the lifting release switching valve 19 and the lowering release switching valve 20 are arranged in the flow dividing section 83.

  Next, FIG. 5 is a cross-sectional view of the diversion section 83. As shown in FIG. 5, the ascending diversion valve 14 and the diversion diversion valve 15 are spaced apart from each other at a predetermined interval in the diversion section 83. It is arranged in parallel with. The ascending diversion valve 14 and the descending release switching valve 20 are disposed on the same axis, and the descending diversion valve 15 and the ascending release switching valve 19 are disposed on the same axis.

  Further, the ascending diversion valve 14 and the ascending release switching valve 19 are arranged on the same one side portion of the diversion section 83, and the descending diversion valve 15 and the descending release switching valve 20 are the same other side portion of the diversion section 83. Is arranged. That is, the ascending diversion valve 14 and the ascending release switching valve 19 are arranged adjacent to each other in the diversion section 83 and vertically, and the descending diversion valve 15 and the descending release switching valve 20 are adjacent in the diversion section 83. They are arranged one above the other. As a result, the assembling passage 23 and the ascending branch passage 24 that connect the ascending diversion valve 14 and the ascending release switching valve 19 can be simplified. Further, the lowering confluence passage 25 and the lowering branch passage 26 connecting the lowering diversion valve 15 and the lowering release switching valve 20 can be simplified.

  Next, the lifting release switching valve 19 includes a spool 72, a spring 75 disposed at the end of the spool 72, and a bottomed cylindrical plug 71 in which a spool hole is formed on the inner surface and accommodates the spool 72 and the spring 75. And have. The bottomed cylindrical plug 71 is formed in a shape that is long in a specific direction. Here, a spool hole 91 having substantially the same diameter and the same diameter is formed in a portion of the valve body 6 where the lifting release switching valve 19 and the lowering diversion valve 15 are arranged on the same axis. The plug 71 is fitted into the spool hole 91 and attached to the valve body 6 by partial screwing. The thickness of the plug 71 is determined according to the outer diameter of the spool 72. Further, the lifting release switching valve 19 and the lowering diversion valve 15 are arranged on the same axis with the bottom 71a of the plug 71 as a boundary.

  Here, the bottom 71a of the plug 71 is, in other words, a partition formed in the spool hole 91 of the descending diverter valve 15, and the lifting release switching valve 19 is disposed on one side of the partition, The descending diversion valve 15 is arranged on the side portion.

  As a result, the lifting release switching valve 19 can be disposed in the same branching section 83 as that of the lowering branching valve 15, and the storage space (spool hole 91) for the lowering branching valve 15 and the lifting release switching valve 19 is provided for the valve body 6. It can be formed by the same hole processing, and it becomes easy to form a spool hole. In addition, it is very difficult to machine holes from the B-B side surface and the C-C direction side surface of the valve body 6 and finish the partition that separates the lifting release switching valve 19 and the lowering diversion valve 15.

  Similar to the lifting release switching valve 19, the lowering release switching valve 20 accommodates the spool 74, a spring 76 disposed at the end of the spool 74, and a spool hole formed in the inner surface to accommodate the spool 74 and the spring 76. It has a bottomed cylindrical plug 73. The bottomed cylindrical plug 73 is formed in a shape that is long in a specific direction. Here, a spool hole 92 having substantially the same diameter and the same diameter is formed in the valve main body 6 at a portion where the lowering release switching valve 20 and the raising diversion valve 14 are arranged on the same axis. The plug 73 is fitted into the spool hole 92 and attached to the valve body 6 by partial screwing. The thickness of the plug 73 is determined according to the outer diameter of the spool 74. Further, the lowering release switching valve 20 and the raising diversion valve 14 are disposed on the same axis with the bottom 73a of the plug 73 as a boundary.

  Here, the bottom portion 73a of the plug 73 is, in other words, a partition wall formed in the spool hole 92 of the ascending flow dividing valve 14, and the ascending flow diverting valve 14 is disposed on one side portion of the partition wall, and the other side That is, the lowering release switching valve 20 is arranged in the portion.

  As a result, the lowering release switching valve 20 can be disposed in the same diversion section 83 as the ascending diversion valve 14, and the storage space (spool hole 92) for the ascending diversion valve 14 and the lowering release switching valve 20 is provided for the valve body 6. It can be formed by the same hole processing, and it becomes easy to form a spool hole. It should be noted that it is very difficult to machine holes from the B-B side surface and the C-C direction side surface of the valve body 6 and finish the partition wall separating the ascending diversion valve 14 and the descending release switching valve 20.

(Activation of multiple direction switching valve)
Next, the operation of the multiple direction switching valve 1 will be described with reference to FIG. First, the boom direction switching valve 11 can be switched to three positions: a raised position 11a, a neutral position 11b, and a lowered position 11c. At the neutral position 11b, the unload passage 21 is communicated, and the assembling passage 23 for raising, the joining passage 25 for lowering, and the boom cylinder 3 are shut off. At the ascending position 11a, the pressure oil from the pump 2 is supplied to the head side chamber 3a of the boom cylinder 3, and the rod side chamber 3b is communicated with the assembling passage 23 for ascending. Thus, when pressure oil is supplied to the head side chamber 3a of the boom cylinder 3 and the boom is raised, the return pressure oil from the rod side chamber 3b of the boom cylinder 3 is supplied to the head side chamber 4a of the bucket cylinder 4, and the bucket It will be held in parallel.

  The bucket parallel movement function when the boom is raised is activated when the ascending branch passage 24 is blocked, that is, when the ascending release switching valve 19 is at the leveling operation position 19a. On the other hand, when the lifting release switching valve 19 is switched to the leveling release position 19b, the lifting branch passage 24 is in communication with the unloading passage 21, and from the rod side chamber 3b of the boom cylinder 3 through the boom direction switching valve 11. The pressure oil pumped to the ascending merge passage 23 is caused to flow from the ascending branch passage 24, and the supply of the pressure oil to the head side chamber 4 a of the bucket cylinder 4 is stopped. That is, the bucket parallel movement function is released.

  Further, when the boom direction switching valve 11 is switched to the lowered position 11c, the pressure oil from the pump 2 is supplied to the rod side chamber 3b of the boom cylinder 3, and the head side chamber 3a is communicated with the lowering junction passage 25. Thus, when pressure oil is supplied to the rod side chamber 3b of the boom cylinder 3 and the boom is lowered, the return pressure oil from the head side chamber 3a of the boom cylinder 3 is supplied to the rod side chamber 4b of the bucket cylinder 4, and the bucket It will be held in parallel.

  This bucket parallel movement function when the boom is lowered is activated when the lowering branch passage 26 is blocked, that is, when the lowering release switching valve 20 is at the leveling operation position 20a. On the other hand, when the lowering release switching valve 20 is switched to the leveling release position 20 b, the lowering branch passage 26 is in communication with the unload passage 21, and the boom side switch 3 via the boom direction switching valve 11 from the head side chamber 3 a of the boom cylinder 3. The pressure oil pumped to the lowering junction passage 25 is caused to flow from the lowering branch passage 26, and the supply of the pressure oil to the rod side chamber 4 b of the bucket cylinder 4 is stopped. That is, the bucket parallel movement function is released.

  Further, when the electromagnetic switching valve 33 of the float electromagnetic valve mechanism 18 is operated, the switching valve 34 and the switching valve 35 are switched to the communicating state regardless of the position of the boom direction switching valve 11, and the boom cylinder 3 The rod side chamber 3 b and the head side chamber 3 a are connected to the tank passage 22. Thereby, for example, when it is desired to perform work such as leveling, the load is run with the electromagnetic switching valve 33 actuated and the bucket is grounded. At this time, since the rod side chamber 3a and the head side chamber 3b are connected to the tank passage 22 in the boom cylinder, the boom is raised and lowered so as to follow the unevenness of the ground, so that work such as leveling can be easily performed.

  Next, the bucket direction switching valve 12 can be switched to three positions: a scoop position 12a, a neutral position 12b, and a dump position 12c. At the rake position 12a, the rod side chamber 4b of the bucket cylinder 4 is connected to the pump 2 and the head side chamber 4a is connected to the unload passage 21 to operate the bucket in the rake direction. At the neutral position 12b, only the unload passage 21 is communicated. At the dump position 12c, the head side chamber 4a is connected to the pump 2 and the rod side chamber 4b is connected to the unload passage 21 to dump the bucket.

  As described above, according to the multiple direction switching valve 1, the switching valves 19 and 20 for canceling the bucket parallel movement function and the branching valves 14 and 15 are arranged in the same branching section. The 20 section can be omitted. As a result, even if new functions such as the ascending sequence valve 16 and the descending diversion valve 15 and the float solenoid valve mechanism 18 are added to the multiple direction switching valve as in the present embodiment, there are many more functions than before. The enlargement of the continuous direction switching valve can be suppressed. That is, it can be set as the compact multiple direction switching valve which has a bucket parallel movement function.

  Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications can be made as long as they are described in the claims. .

It is a hydraulic circuit diagram which shows the multiple direction switching valve which has a bucket parallel displacement function which concerns on one Embodiment of this invention. It is a top view of the multiple direction switching valve shown in FIG. It is a BB direction side view of the multiple direction switching valve shown in FIG. It is CC direction side view of the multiple direction switching valve shown in FIG. It is AA sectional drawing of the multiple direction switching valve shown in FIG.

Explanation of symbols

1: Multiple direction switching valve 2: Pump (hydraulic power source)
3: Boom cylinder 4: Bucket cylinder 5: Tank 11: Boom direction switching valve 12: Bucket direction switching valve 14: Lifting diversion valve 19: Lifting release switching valve 21: Unload passage 22: Tank passage 23: Lift Junction passage 24: Ascending branch passage 82: Boom section 83: Dividing section 85: Bucket section

Claims (4)

An unload passage connected to the hydraulic source;
A tank passage connected to the tank;
A boom direction switching valve disposed in the boom section and connected to the unload passage to control the supply of pressure oil from the hydraulic source to the boom cylinder;
A bucket directional control valve disposed in a bucket section and connected to the unload passage to control the supply of pressure oil from the hydraulic source to a bucket cylinder;
An assembling passage for ascending to supply pressure oil from the rod side chamber of the boom cylinder to the head side chamber of the bucket cylinder through the boom direction switching valve;
An ascending diversion valve that is disposed in the diversion section and is provided in the assembling passage for ascending, and controls the flow rate of the pressure oil supplied to the head side chamber of the bucket cylinder;
An ascending branch passage branched from the ascending confluence passage and connected to the unload passage or the tank passage;
An ascending release switching valve disposed in the diversion section and provided in the ascending branch passage and blocking or communicating with the ascending branch passage;
A lowering confluence passage for supplying pressure oil from the head side chamber of the boom cylinder to the rod side chamber of the bucket cylinder via the boom direction switching valve;
A lowering diverter valve disposed in the diverting section and provided in the lowering confluence passage for controlling the flow rate of the pressure oil supplied to the rod side chamber of the bucket cylinder;
A lowering branch passage branched from the lowering junction passage and connected to the unload passage or the tank passage;
A lowering release switching valve that is disposed in the branching section and is provided in the lowering branch passage and shuts off or communicates with the lowering branch passage;
The descending diversion valve and the ascending diversion valve are arranged in parallel to each other,
The ascending diverter valve is disposed on one side of the diverter section, and the descending diverter valve is disposed on the other side of the diverter section;
The multiple direction switching valve having a bucket parallel movement function, wherein the ascending release switching valve is disposed on the one side portion on the same axis as the descending diversion valve. In the multiple direction switching valve having a bucket parallel movement function according to claim 1 ,
The ascending release switching valve has a bottomed cylindrical plug with a spool hole formed on the inner surface,
The multiple direction switching valve having a bucket parallel movement function, wherein the lowering diversion valve and the raising release switching valve are arranged on the same axis line with the bottom of the plug as a boundary. An unload passage connected to the hydraulic source;
A tank passage connected to the tank;
A boom direction switching valve disposed in the boom section and connected to the unload passage to control the supply of pressure oil from the hydraulic source to the boom cylinder;
A bucket directional control valve disposed in a bucket section and connected to the unload passage to control the supply of pressure oil from the hydraulic source to a bucket cylinder;
A lowering confluence passage for supplying pressure oil from the head side chamber of the boom cylinder to the rod side chamber of the bucket cylinder via the boom direction switching valve;
A lowering diverter valve disposed in the diverting section and provided in the lowering confluence passage for controlling the flow rate of the pressure oil supplied to the rod side chamber of the bucket cylinder;
A lowering branch passage branched from the lowering junction passage and connected to the unload passage or the tank passage;
A lowering release switching valve disposed in the branching section and provided in the lowering branch passage, and shuts off or communicates with the lowering branch passage;
An assembling passage for ascending to supply pressure oil from the rod side chamber of the boom cylinder to the head side chamber of the bucket cylinder through the boom direction switching valve;
An ascending diverter valve disposed in the diverting section and provided in the ascending merge passage to control the flow rate of the pressure oil supplied to the head side chamber of the bucket cylinder;
An ascending branch passage branched from the ascending confluence passage and connected to the unload passage or the tank passage;
An ascending release switching valve disposed in the diversion section and provided in the ascending branch passage and blocking or communicating with the ascending branch passage;
The descending diversion valve and the ascending diversion valve are arranged in parallel to each other,
The ascending diverter valve is disposed on one side of the diverter section, and the descending diverter valve is disposed on the other side of the diverter section;
The multiple direction switching valve having a bucket parallel movement function, wherein the lowering release switching valve is disposed on the other side portion on the same axis as that of the lifting diversion valve. In the multiple direction switching valve having a bucket parallel movement function according to claim 3 ,
The lowering release switching valve has a bottomed cylindrical plug in which a spool hole is formed on the inner surface,
The multiple direction switching valve having a bucket parallel movement function, wherein the ascending diversion valve and the descending release switching valve are arranged on the same axis line with the bottom of the plug as a boundary.

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